The doctor study programme is devoted to the preparation of the high quality scientific and research specialists in various branches of electrical engineering, namely in theory of electromagnetism, electrical circuits, general methods of signal processing and electrical measurements.
The aim is to provide the doctor education in all these particular branches to students educated in university magister study, make deeper their theoretical knowledge, to give them also some practical knowledge for their individual scientific work.

The doctors are able to solve scientific and complex engineering tasks from the area of electrical engineering and electromagnetism.
Wide fundamentals and deep theoretical basis of the study program bring high adaptability and high qualification of doctors for the most of requirements of their future creative practice in all areas of electrical engineering.
The doctors are competent to work as scientists and researchers in many areas of basic research or research and development, as high-specialists in the development, design, construction, and application areas in many institutions, companies, and organisations of the electrical and electronic research, development, and industry as in the areas of electrical services and systems, inclusively in the special institutions of the state administration. In all of these branches they are able to work also as the leading scientific-, research-, development- or technical-managers.

Students who finish this study area are able to deal with scientific and complex engineering tasks from the sphere of general electrical engineering and electromagnetism.
The PhD graduates are, owing to the developed high-quality theoretical education and specialization in the chosen field of study, sought as specialists in the area of general electrical engineering.
In the sphere of general electrical engineering and electromagnetism, the PhD graduates will be competent to work as scientific and research workers in basic and applied research, as specialized development, construction and operation experts in various research and development institutions, electrotechnical and electronic production companies and corporations and with producers and users of electrical systems and devices, where they will be able to make use of modern computer and measurement techniques in a creative way.

prof. Ing. Jarmila Dědková, CSc.

1. An optimization of ion microclima in living areas

   Content of this work is an experimental and theoretical research of mechanism of the air ion generation, with objective in an optimization of spectral composition of ion fields in living areas. The model of ion generation will be developed, with defined temperature, ion concentration, and humidity, as well as with electric and magnetic field. Part of this work will be an optimization of method for ion concentration and spectrum measurement and design of appropriate sensors.

   Tutor: Steinbauer Miloslav, doc. Ing., Ph.D.

2. Detection and localization of partial discharges in power oil transformers

   One of the crucial issues of power oil transformers reliability is the presence and rate of partial discharges. The increased activity of partial discharges may cause a critical situation resulting in explosion and transformer destruction. In order to avoid the state of disrepair it is necessary to observe the level of partial discharges. An useful information contributing to failure probability estimation is a localization of partial discharge activity. It might be observed the typical manifestations of discharge activity as electromagnetic or acoustics emission. The topic of the thesis is a study of the state of the art in field of partial discharge activity localization. The goal is the development of localization methods into applicable state. It is desirable to design a multi-method utilization in order to localization accuracy improvement.

   Tutor: Drexler Petr, doc. Ing., Ph.D.

3. Experimental models for elektrical impedance tomography

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   Tutor: Bartušek Karel, prof. Ing., DrSc.

4. Experimental research of magnetic susceptibility measurements techniques by MRI.

   Will be studied the MRI experimental techniques of the magnetic susceptibility measurements. Design and experimental verification of MRI techniques will be perform on biological objects.

   Tutor: Bartušek Karel, prof. Ing., DrSc.

5. Fast MRI techniques

   Sudent will curry out the analysis of the fast MRI techniques, he will concentrate on selected techniques suitable for relaxation and diffusion measurement for the samples with short relaxation times.

   Tutor: Bartušek Karel, prof. Ing., DrSc.

6. Methodology Development of Subject Delimitation of Microbial Colonies

   The aim of the work is analysis and follow up sorting of microbial colonies using optic, spectroscopic and other methods in preanalytical phase of classification in identification process of clinical microbiology.

   Tutor: Bartušek Karel, prof. Ing., DrSc.

7. Modification of EIT methods for soil electrical conductivity mapping

   The work is oriented to the development and the verification of methods to determinate an electrical conductivity of soils. The detection of object properties is realize using methods based on EIT. The aim of the research work is to find and experimentally verify the stable and not time-consuming algorithms with respect to required accuracy.

   Tutor: Dědková Jarmila, prof. Ing., CSc.

8. MRI relaxometry of contrast agents.

   Will be studied the MRI relaxometry (T1, T2) of the contraast agents with short relaxation times.Design and experimental verification of MRI techniques will be perform on biological objects.

   Tutor: Bartušek Karel, prof. Ing., DrSc.

9. Numerical models of stochastic problems

   In the process of modeling of large-scale problems the multiparametric tasks occure with an explicit description of the minimum parameters. In numerical modeling some approaches exist for such models. Basic two can be characterized as deterministic and nondeterministic process. Both approaches can be used in numerical modeling of large-scale problems associated with electrical engineering, electronic and electromagnetic fields. When suitable formulated, they become powerful tools in the scientific approach to solving of basic and applied research. The aim of doctoral study is to describe and define the two approaches and then experimentally verify the properties of models, explicitly on nanomaterial models.

   Tutor: Fiala Pavel, prof. Ing., Ph.D.

10. The light wave propagation in the ion field

    The aim of this Ph.D. thesis is the theoretical and experimental research of the ion field concentration influence on the mechanism of light wave propagation. Within the research a theoretical analysis of light wave propagation in the low and mid concentrated ion field will be carried out. A suitable measurement method utilizing light wave state change detection will be designed and experimentally verified. An analysis of real potential of realized method to ion field concentration quantification is supposed.

    Tutor: Drexler Petr, doc. Ing., Ph.D.